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Protection of CD4+ T Cells From Hepatitis C Virus Infection-Associated Senescence via ΔNp63-miR-181a-Sirt1 PathwayZhou, Yun, Li, Guang Y., Ren, Jun P., Wang, Ling, Zhao, Juan, Ning, Shun B., Zhang, Ying, Lian, Jian Q., Huang, Chang X., Jia, Zhan S., Moorman, Jonathan P., Yao, Zhi Q. 27 June 2016 (has links)
T cell dysfunction has a crucial role in establishing and maintaining viral persistence. We have previously shown a decline in miR‐181a, which regulates CD4+ T cell responses via DUSP6 overexpression, in individuals with hepatitis C virus (HCV) infection. Here, we describe accelerated T cell senescence in HCV‐infected individuals compared with age‐ and sex‐matched healthy subjects. Mechanistic studies revealed that up‐regulation of transcription factor ΔNp63 led to the decline of miR‐181a expression, resulting in an overexpression of the antiaging protein Sirt1, in CD4+ T cells from HCV‐infected individuals. Either reconstituting miR‐181a or silencing ΔNp63 or Sirt1 expression in CD4+ T cells led to accelerated T cell senescence, as evidenced by an increased senescence‐associated β‐galactosidase (SA‐β‐gal) expression, shortened telomere length, and decreased EdU incorporation; this suggests that HCV‐induced T cell senescence is counterregulated by the ΔNp63–miR‐181a–Sirt1 pathway. An increase of IL‐2 production was observed in these senescent CD4+ T cells and was driven by a markedly reduced frequency of Foxp3+ regulatory T (Treg) cells and increased number of Foxp3− effector T (Teff) cells upon manipulating the ΔNp63–miR‐181a–Sirt1 pathway. In conclusion, these findings provide novel mechanistic insights into how HCV uses cellular senescent pathways to regulate T cell functions, revealing new targets for rejuvenating impaired T cell responses during chronic viral infection.
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Expression Of Hepatitis C Viral Non-structural 3 Antigen In Transgenic ChloroplastsBhati, Anubhuti 01 January 2005 (has links)
Hepatitis C viral infection is the major cause of acute hepatitis and chronic liver disease and remains the leading cause of liver transplants (NIH). An estimated 180 million people are infected globally (WHO). There is no vaccine available to prevent hepatitis C. The treatment with antiviral drugs is expensive, accompanied with various side effects and is limited only to those at risk of developing advanced liver disease. The treatment is also effective in only about 30% to 50% of treated patients and still a high percentage of patients are resistant to therapy. Therefore, there is an urgent need for the development of effective vaccine antigens and an efficacious HCV vaccine. The non-structural 3 protein of the hepatitis C virus is a multifunctional protein of the virus required for virus polyprotein processing and replication. Vaccine antigen production via chloroplast transformation system usually results in high expression levels and eliminates the possibility of contamination with vector sequences,human or animal pathogens. The HCV NS3 antigen was expressed in the chloroplast of Nicotiana tabacum var. Petit havana and LAMD-609. The 1.9kb NS3 gene was cloned into a chloroplast expression vector, pLD-Ct containing the 16S rRNA promoter, aadA gene coding for the spectinomycin selectable marker, psbA 5' untranslated region to enhance translation in the light and 3' untranslated region for transcript stability and trnI & trnA homologous flanking sequences for site specific integration into the chloroplast genome. Chloroplast integration of the NS3 gene was first confirmed by PCR. Southern blot analysis further confirmed site-specific gene integration and homoplasmy. The NS3 protein was detected in transgenic chloroplasts by immunoblot analysis. The NS3 protein was further quantified by ELISA. Maximum expression levels of NS3 up to 2% in the total soluble protein were observed even in old leaves, upon 3-day continuous illumination. These results demonstrate successful expression of the HCV non-structural 3 antigen in transgenic tobacco chloroplasts. Animal studies to test the immunogenecity of the chloroplast derived HCV NS3 will be performed using chloroplast derived NS3 antigen.
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Updated epidemiology of hepatitis C virus infections and implications for hepatitis C virus elimination in GermanyTergast, Tammo L., Blach, Sarah, Tacke, Frank, Berg, Thomas, Cornberg, Markus, Kautz, Achim, Manns, Michael, Razavi, Homie, Sarrazin, Christoph, Serfert, Yvonne, van Thiel, Ingo, Zeuzem, Stefan, Wedemeyer, Heiner 27 November 2023 (has links)
In 2014, an analysis was conducted to evaluate the hepatitis C virus (HCV) epidemiology
and disease burden in Germany. Since then, there have been considerable developments
in HCV management such as the implementation of direct acting antivirals.
The aim of this analysis was to assess the recent data available for Germany, establish
an updated 2020 HCV prevalence and cascade of care and evaluate the impact of
what-if
scenarios on the future burden of disease using modelling analysis. A dynamic
Markov model was used to forecast the HCV disease burden in Germany. Model inputs
were retrieved through literature review, unpublished sources and expert input.
Next, three “what-if”
scenarios were developed to evaluate the status quo, COVID-19
pandemic, and steps needed to achieve the WHO targets for elimination. At the beginning
of 2020, there were 189,000 (95% UI: 76,700–295,000)
viremic infections in
Germany, a decline of more than 85,000 viremic infections since 2012. Annual treatment
starts went down since 2015. Compared with 2019, the COVID-19
pandemic
resulted in a further 11% decline in 2020. If this continues for two years, it could result
in 110 excess HCC cases and 200 excess liver related deaths by 2030. To achieve the WHO targets, 81,200 people need to be diagnosed, with 118,600 initiated on treatment
by 2030. This could also avert 1,020 deaths and 720 HCC cases between 2021
and 2030. Germany has made strides towards HCV elimination, but more efforts are
needed to achieve the WHO targets by 2030.
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Evolutional transition of HBV genome during the persistent infection determined by single-molecule real-time sequencing / 1分子リアルタイムシーケンシングを用いたB型肝炎ウイルス持続感染下におけるウイルスゲノムの進化的変遷の解析Arasawa, Soichi 24 July 2023 (has links)
京都大学 / 新制・課程博士 / 博士(医学) / 甲第24841号 / 医博第5009号 / 新制||医||1068(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 朝長, 啓造, 教授 波多野, 悦朗, 教授 竹内, 理 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Correlates of Hepatitis-C virus Testing, Diagnosis, and Treatment Rates among Clients in Criminal Rehabilitation FacilitiesCannon, Sara 04 September 2018 (has links)
No description available.
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Characterization of Occult Hepatitis B Virus Infection in HIV-Positive IndividualsMartin Quigley, Christina M. 20 September 2011 (has links)
No description available.
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Examining Virus Interactions with Host Serine Hydrolases in ImmunometabolismStern, Tiffany 12 January 2024 (has links)
As obligatory intracellular parasites, viruses are in a constant battle with their host to establish infection. They can facilitate their propagation by modulating host immune or metabolic pathways. This modulation involves targeting various molecular factors such as microRNAs (miRNA), enzymes, or small molecules. Understanding how viruses alter the chemical makeup of a cell is crucial to identifying what pathways are being targeted, furthering our understanding of the virus life cycle, and may aid in identifying biomarkers of disease. Here, we examine host-virus interactions in the context of two viruses, hepatitis c virus (HCV) and severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). First, the modulation of serine hydrolases by a pro-viral microRNA, miRNA-122, is investigated using activity-based protein profiling (ABPP). This study identifies a downstream target of miRNA-122 that is differentially activated during HCV infection which can be targeted pharmacologically to reduce HCV infectivity. Second, we apply similar techniques to identify serine hydrolase changes associated with SARS-CoV-2 infection. Results point towards enrichment of endocannabinoid metabolism which may offer an alternative therapeutic avenue for combating SARS-CoV-2 infection. Together, the work presented in this thesis provides avenues for further investigation into miRNA-122 interactions during HCV infection and endocannabinoid metabolism in SARS-CoV-2 infection.
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Hepatitis B x Antigen Promotes "Stemness" in the Pathogenesis of Hepatocellular CarcinomaFriedman, Tiffany Ilene January 2012 (has links)
Hepatitis B virus (HBV) is a major etiologic agent of chronic liver disease (CLD) and hepatocellular carcinoma (HCC). The virally encoded X antigen, HBx, contributes importantly to the development of HCC through its trans-activating role in various signal transduction pathways. Pathways implicated in stem cell self-renewal also contribute to carcinogenesis. Thus, experiments were designed to test if HBx triggers malignant transformation by promoting properties that are characteristic of cancer stem cells (CSCs). To test this hypothesis, HBx expressing (HepG2X) and control (HepG2CAT) human cell lines were assayed for phenotypic and molecular characteristics of "stemness." Western blotting of protein extracts from HepG2X and HepG2CAT cells as well as immunohistochemical staining of HCC and adjacent liver tissue sections from HBV infected patients showed up-regulation of "stemness"-associated (EpCAM and beta-catenin) and "stemness" (Oct-4, Nanog, Klf-4) markers by HBx. Moreover, HBx stimulated cell migration and spheroid formation. HBx expression was also associated with depressed levels of E-cadherin and subsequent activation of beta-catenin and EpCAM. Results from ChIP-chip data performed previously in this lab suggest an associative link between HBx and the expression of epigenetic co-repressor, mSin3A, which is known to repress E-cadherin when complexed with histone deacetylases. Thus, experiments were also designed to test if HBx represses the E-cadherin gene (CDH1) through histone deacetylation by the mSin3A/HDAC complex. In HepG2X cells, decreased levels of E-cadherin and elevated levels of mSin3A were detected. Reciprocal immunoprecipitation with anti-HBx and anti-mSin3A demonstrated mutual binding. Further, HBx-mSin3A co-localization was showed by immunofluorescent staining. Chromatin immunoprecipitation revealed that HBx mediated the recruitment of the mSin3A/HDAC complex to the CDH1 promoter. HDAC inhibition by Trichostatin A treatment restored E-cadherin expression. Thus, HBx-associated epigenetic repression of E-cadherin and up-regulated expression of multiple "stemness" markers support the hypothesis that HBx contributes to hepatocarcinogenesis, at least in part, by promoting changes in gene expression that are characteristic of CSCs. This work is the first to propose that HBV promotes "stemness" in the pathogenesis of HCC. / Biology
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Short Chain Fatty Acids (SCFAs) delay the pathogenesis of Hepatitis B Virus (HBV)-associated Hepatocellular Carcinoma (HCC)McBrearty, Noreen G January 2019 (has links)
Chronic infection with hepatitis B virus (HBV) is a primary risk factor for the development of hepatocellular carcinoma (HCC). HCC is the fifth most common cancer type worldwide with few treatment options. The hepatitis B encoded x antigen (HBx) plays a crucial role in the pathogenesis of HCC through several mechanisms. HBx alters signaling pathways shown to promote carcinogenesis and mediates epigenetic changes that silence tumor suppressor genes and activate host oncogenes. Short chain fatty acids (SCFAs) are made by selected gut bacteria with largely anti-inflammatory properties. They alter gene expression by functioning as histone deacetylase inhibitors (HDACi) and can bind to G protein coupled receptors (GCPR) to stimulate signaling pathways. Due to the documented anti-cancer properties of SCFAs, experiments were designed to test the hypothesis that SCFAs delay the development of HCC in HBx transgenic (HBxTg) mice. A diet of SCFAs was fed to HBxTg for three months prior to the expected appearance of dysplastic nodules and HCC. The results showed a statistically significant reduction in the number of dysplastic nodules as well as the presence and frequency of HCC. The effect of SCFAs on tumor growth was also evaluated in nude mice subcutaneously injected with human HCC cells. Tumor size in SCFA-treated mice was statistically smaller compared to the controls. The effect of SCFAs on cell viability of cancer and primary human hepatocytes was evaluated. SCFAs were shown to reduce cell viability in cancer cells only, with no effect on primary hepatocytes. Proteomics was performed on SCFA-treated compared to control livers from HBxTg to investigate changes on the molecular level that are associated with reduced preneoplastic and neoplastic nodule formation. Pathway analysis showed a decrease in important cancer-promoting pathways altered by HBx in HCC, including inflammation, oxidative stress, PI3K, VEGF, EGF, and Ras. These pathways are involved in biological processes central to carcinogenesis such as cell proliferation, survival, and angiogenesis. The ability of SCFAs to decrease these pathways has never been demonstrated. Further investigation confirmed that Ras activity was decreased in 12-month old livers treated with SCFAs. Taken together, these results show that SCFAs are capable of delaying the rate of tumor growth and tumor frequency in two mouse models of HBV-associated HCC, as well as reduce cell viability in cancer cells specifically. This data suggests that SCFAs may be a novel treatment option for HBV-associated HCC. / Biology
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Vaccine Development Against Porcine Epidemic Diarrhea Virus Utilizing the Hepatitis B Virus Core Antigen ProteinGillam, Francis 11 January 2018 (has links)
Porcine epidemic diarrhea Virus (PEDV) is a virus effecting swine. It is the cause of disease that manifests with symptoms ranging from depression, to severe dehydration and death. Young piglets are particularly susceptible to the virus, which can reach mortality rates of 100%. Presence of the virus on a swine farm can therefore cause severe economic losses. Treatments currently exist for PEDV, but are mostly generated from the virus itself. There has recently been renewed interest in a vaccine that is made from a different source, which might help eliminate some of the side effects of those that currently exist on the market.
This project outlines three experiments performed in animals. During the first experiment, a structural protein from the Hepatitis B virus was genetically altered to include important structural portions of PEDV. This new protein is generated in E. coli and purified. After purification, the protein assembles into a virus-like particle (VLP). VLPs are structural proteins of existing viruses that are expressed and assembled to mimic the virus. By doing so, the immune system recognizes the protein as a potential threat, and launches a response in the form of antibodies. Manipulations of the VLPs as describe herein allow the new vaccine to generate antibodies toward other diseases such as PEDV. Although all five of the vaccines used in the first experiment were able to generate appropriate antibodies, only two of them were effective at preventing PEDV from entering susceptible cells (virus neutralization).
A second experiment, with three newly designed vaccines was therefore performed. This experiment, like the first, was successful in producing antibodies to several of the included PEDV protein sections, but none were able to neutralize the virus. These results led to a third experiment, during which further design improvements were made to the basic vaccine structure in an attempt to increase the neutralization capabilities of the vaccines. The results from the third experiment indicated that several changes to the vaccine increased the immune response to the structural portions of PEDV, providing a better overall vaccine candidate. This also led to the conclusion that one specific sequence from PEDV has a better ability to neutralize the virus than the other sections. / PHD / Porcine epidemic diarrhea Virus (PEDV) is a virus effecting swine. It is the cause of disease that manifests with symptoms ranging from depression, to severe dehydration and death. Young piglets are particularly susceptible to the virus, which can reach mortality rates of 100%. Presence of the virus on a swine farm can therefore cause severe economic losses. Treatments currently exist for PEDV, but are mostly generated from the virus itself. There has recently been renewed interest in a vaccine that is made from a different source, which might help eliminate some of the side effects of those that currently exist on the market.
This project outlines three experiments performed in animals. During the first experiment, a structural protein from the Hepatitis B virus was genetically altered to include important structural portions of PEDV. This new protein is generated in E. coli and purified. After purification, the protein assembles into a virus-like particle (VLP). VLPs are structural proteins of existing viruses that are expressed and assembled to mimic the virus. By doing so, the immune system recognizes the protein as a potential threat, and launches a response in the form of antibodies. Manipulations of the VLPs as describe herein allow the new vaccine to generate antibodies toward other diseases such as PEDV. Although all five of the vaccines used in the first experiment were able to generate appropriate antibodies, only two of them were effective at preventing PEDV from entering susceptible cells (virus neutralization).
A second experiment, with three newly designed vaccines was therefore performed. This experiment, like the first, was successful in producing antibodies to several of the included PEDV protein sections, but none were able to neutralize the virus. These results led to a third experiment, during which further design improvements were made to the basic vaccine structure in an attempt to increase the neutralization capabilities of the vaccines. The results from the third experiment indicated that several changes to the vaccine increased the immune response to the structural portions of PEDV, providing a better overall vaccine candidate. This also led to the conclusion that one specific sequence from PEDV has a better ability to neutralize the virus than the other sections.
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